Centrifugal battery control system



April 30, 1957 J. B. BANGE, JR 2,790,553

CENTRIFUGAL BATTERY CONTROL SYSTEM Filed June 20, 1955 4 Sheets-Sheet 1 LLL April 30 1957- J. B. BANGE, JR 2,790,553

CENTRIFUGAL BATTERY CONTROL SYSTEM Filed June 20, 1955 `4 Sheets-Sheet 2 WIST. wws epsva ,5' Wsw 555W V7' T2, 75TH 7 Desp @v3 rQsy/ 55V/ vLsvz 553V@ CRS CRI l] s (f) l PT E E Mmmm CT f 55 f f' I l mmm/T mereucar/ 'l'f if T [mmm l' l n G2 o gil 'L5/AD ,/QD sgvfngg M E XCR L i A .DGM A' q' Rl R2 1.125 y U3 [1:11 S MNUALRECYCLE um I Pa] un D Y FMS l LH I 49 A 45- .1f E @552' 4 a 46 l o F 2/ l 4 7 /5 G4 i 'r I 948 o t!" 55 1%/ 55 6:5A 5768.M 45

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CENTRIFUGAL BATTERY CONTROL SYSTEM yApfil 3o, 1957 Yifi-fad Juneo, 1955 4 Sheets-Sheet 3 DMS BR CRI CT/ ffl-21M 197mg @hun l ATTORNEYS April Filed June 20. 19.55

J. B. BANGE, JR

CENTRIFUGAL BATTERY CONTROL SYSTEM 4y Sheets-Sheet 4 CRI CRI CRI CRIl RECYCLING R l l 13s s R FOR MA c/-l/NE N/ m55 T/R |7.'O. "Bs T2 FoR MA CHINE N2 n Tc.' 1ra U85 T2R I B575 FOR MA CHINE/V05 m 7.'c"72o. UBSTSR HBS Tf FOR MACH/NE N4 A I TC' 'a Oesrn l |8575 FOR MA CHINEN$ m ml I 1:0. UesTsR B576 FOR MACHINEN6 m Tcl ITTO UBSTSR BST? FOR MACH/NE N 7 m l r 'm A wasn/2 5571s FOR MACH/NEA/"e m Tc.' 7:0. UBSTBR @sT/R v f I i Us sTR nBSTZR fT\ UTD/z |B$T5R l l i "BSTM B SI1-SR n TORI -I I -1BST5R l U i LBSTGR ToR/ 7 '0R/ l 771'? (4ux)| I I To.

' OUT TIME 1 5576/? TIMER o7- .s l l "BSTR, l u, CLI/7CH l :j IIoT ,Y Z 1L/2o... lv BSTRZ fg ,n j U L 1 GROUP SEQUENc/NG J lNvE/INTOR Jr o fg@ f 55"* KR ATTORNEYS gauw United States latent i CENTRIFUGAL BATTERY CONTRL SYSTEM Joseph B. Bange, Jr., Hamilton, Ohio, assignor to The Western States Machine Company, Hamilton, Ohio, a corporation of Utah Application June 20, 1955, Serial No. 516,605

6 Claims. (Cl. 21o- 138) This invention relates to a control system to supervise the operation of a battery of heavy cyclical centrifugal machines of the type used in the manufacture and retining of sugar.

In the use of a battery of several such machines, it is important to stagger the starting of the respective cycles of operation, for otherwise the large amount of power required for the acceleration of each machine will be demanded by several machines simultaneously and the resulting power peaks will either overload the source of power for the battery or require an inordinately expensive power source. Even when the centrifugal machines .are operated under automatic control, there is a possibility' of overburdening the power source with overlap- :ping power peaks, because of the fact that the duration .of certain operations in the cycle of each machine, for example, the loading time, the braking time, or the distcharging time, is susceptible to variation.

An important object of this invention is to provide a `control system for a battery of heavy cyclical centrifuigal machines whereby the cycles of operations of the sev- .eral machines are started and maintained automatically in .a desired stagged relationship so that the danger of overloading the source of power for the battery by the concurrent acceleration of several machines is avoided.

Another object is to provide such a battery control system which, after starting the cycles of the several centrifugals in a desired staggered relationship, will become inactive and allow each machine to run and repeat its cycles independently under its own automatic control system.

Still another object is to provide such a battery control system whereby, if the cycles of two or more Vofthe machines in operation should happen to coincide suflciently that a power overload may be imminent, all the machines will be stopped after completing their pending cycles and will then be restarted automatically in a definitely timed sequence.

A further object of this invention is to provide a battery control system whereby the cycle time and productivity of the several centrifugals of the battery can be selected and maintained at any desired value within the capacity of the battery, without discontinuing the service of any of the machines.

According to the present invention, each of the heavy cyclical centrifugal machines in a battery or installation of a plurality of such machines is provided with its own control system for automatically programming the machine through a predetermined cycle of operations independently of the cycles of the other machine; each individual control system is provided with recycling means for causing it to enter into and automatically to repeat its cycle; and a battery control is provided which has elements so connected with and operative upon the respective recycling means of the several machines that the starting of their respective cycles of operation is brought about inra definitely timed sequence. To this end, the battery control comprises a plurality of actuators respectively op- Ytery control.

l 2,790,553 Patented Apr. 30, 1957 erable to activate the individual recycling means of the several machines, together with timing means which have a plurality of correlated timing elements operated successively at predetermined intervals to operate the several actuators in a predetermined sequence.

According to another feature of the invention, the battery control also is provided with means rendered operative upon the starting of the last-to-be-started machine of the battery for inactivating the battery control, so that the several machines thereafter will repeat'their respective cycles independently of each other and of the battery control. In this way, each machine is able to give its maximum production according to its own automatically controlled program of operation, without any limitation upon or interference with its ethciency by the action of the battery control.

Because of the variable duration of certain operations in the cycle of each machine, however, there is a likelihood that the machines of the battery gradually will lose the ordered relationship of their cycles to such an extent that overlapping periods of acceleration of two or more of the machines may make imminent an excessive drain on the source of power for the battery. The occurrence of such a drain or power overload is prevented, according to a further feature of this invention, through the provision in the battery control of means which, upon the occurrence of an inordinate power flow to the battery, will operate to terminate the recycling of all the machines and thus cause them to complete their pendingrcycles and come to rest. This means may include a current responsive device connected with the power feed lines to the battery and operable through the battery control to inactivate the recycling means in the individual control systems of all the machines. When all the machines have come to rest, the aforesaid timing means of the battery control are started automatically through connections in that control, whereupon the several machines of the battery will be restarted on their respective cycles in the desired timed sequence.

According to a further embodiment of this invention, the battery control is also provided with means whereby the total productivity of the battery can be varied at will between a maximum value determined by the minimum duration of the respective independent cycles of the machines and any desired lesser value. This variability is brought about without either removing machines from production or objectionally lengthening the high speed operation of the individual machines, since either of those ice expedients may lead to costly troubles if the machines- -Thus, each cycle of each machine of the battery may be followed by an adjustable period of out time during which the machine will be inactive, before the next cycle of the same machine is started by the action of the bat- Other objects, features and advantages of the invention will appear from the following detailed description and the accompanying drawings of an illustrative embodiment thereof. v

In the drawings:

Fig. 1 is a schematic view of a plurality of heavy cyclical centrifugal machines associated with their indivifl` ual control systems` andY with acommon lbattery.control in accordance with this invention;

Fig. 2 is a diagrammatic side, elevation, partly in sec- ``tion, showing-atypical centrifugal-machine oftherbattery in Iassociation fwithf its main functional "elernerits;

lFig. 3 vis a yschematic'view of'certain elementslof the individual control system of 'the 'typicaimachin Fig. 4 is aschematic-*view of control panels included in "such'an individual control-system;

4Fig.`5 isf'an elementary wiring diagram indicating the manner of operation ofl each individual control system;

I Fig. 5a is va diagram "of thel motor controlci'rcuit of v1eac'hceiitr-ifugal machine; and

iF-ig. 6`l'is-an elementary wiring'diagramridicatingthe "marinerl of operation'- of Ethe battery-`contro1 system.

'11n Fig.;t l" of 'the'fdrawingaa cyclical centrifugall installaitien is 'shown fdiagrammatically, f comprising la 3" battery fcontrol fpnel Pl which supports Lthe principal *components of the battery cont-roland afplu'rality f heavy "c.yc l1' 'c",al centrifugal machines' such; 1s-@10j 11ra`d`12. The I several 'machines have their ewnfindividual 1controll panels 'PZconnected with thel'batteryfpanel Plfthrough cables 1311, 13b,l1-3c,"e'tc. 1The'se-centr`ifugalimachines 'are of the fully automatic type, i.f"e.,theygoautomatically through Xtlie `-f ur'ictions lof i loading; centrifuging' and dis- -fcharging,` and then 'they are recycled-automatically. yOnly 'threecentrifu'gals have been' diagrarnrned inFig.` 1. The systemillu`strated-lis-adaptedl forA eightmachin-es, but it is tobeVV understood that any desired numberl'of centrifugals 'imayibeemployed in' a-battery. Y vAEachcentrifugal machine'. embodies`-`stru`ctures and' coniftrols of. the types disclosed' -in United StatesV Patent No. 12,667,974, Iissued February 12, v1954, in 'the vnarneof .I osephHertrichlfor HeavyCyclical Centrifugal Ma- -.chine -Thel'oadingl-gate servingfeach machine isf'conitrolledaccordingto the y' disclosure of lav copending -ap- 2plicationf/SerialANo.` 261,258, filed-December l2, 1-951, 'now Patentf No. -2,727,630. The f curb of the-machine imay havelafslidingl cover coordinated with the operation dof -theloading'gateaccording tothe disclosure Vof'a copending .application VSerial-No. 441,369, filed ulyfi,

1954, which is assigned to the samepartyasthe .present application *Moret particularly,lasl'indicated in 'Figi-2' of the *draw- 1 ings,l each centrifugal has' ailarge perforated basket 14 :carried.'bytheilower-end-of a spindlelS which is' suspended in'l aagyratory mannerfromna suitable head1 19 supported ltby?ahangerhstructurelzllfrom framework F.' A large r:electricrnotor MMflmay belusedfasithe prime moverl of the: machine, its l:shaft TAbeing connected directly vfia/ith :f spindle '.18 i through lstructures inthe-- -head 19,!in knc'iwn Mmanner.

:Motor :1MM: is -operative upon the 'g basket f1.4 in' a f elo'ckwise-'directiomIas viewed Ifrom above'l'in Fig.V l2. This direction 'of rotation continues through 'the cent-rifugving-'operation andwhiletheibasket isbeing decelerated r to term'nateeach spinning period. Discharging is brought about *with Ethe Ybasket rotatingat alowspeedlinthe H oppositedirectionunderfthe influence ofa lowspee'dor -discharge drive DD-which comprises a clutchtnot shown) -having its driving element `powered `by a `motor DM .at the top of the" main motor MM. Thedischargeclutch Yis yactivewhen-'compressed air is admitted to itthrough line '62 froma-'solenoidfvalveDCSV (Fig. 3). The'air ipressureexpands the driving clutch element intoengage- ,ment` with `the drivenelement. Solids then inthe basket are discharged by the action of mechanical discharger shoe 33 which extends in the direction ofthe normal y ba'sket rtation so' 'that it vcan act only" when thel basket 'is'ldrivven'inthereversediretion. p Dec'elerationlfrom thef'centrifuging" speed f is ,brought about by a combination of regenerative brakiigandif'riction braking, although friction braking -alneean bej'sed "if-desired., iMotor is '-maidefwith'bthrhigh peed windings which are, energized, Y respectively, through con tactors H and L (Fig. 4) by controls to be described hereinafter. The motor is switched from the high speed winding to the low speed winding at the end of the desired 6 period of full speed operation, in order to bring about a suitable interval of regenerative braking utilizing the retarding action of the low speed motor winding. After such 'an intervalgthe motor is completely'deenerg'ized and kfriction braking ensues to complete the normal deceleration of the basket. For friction braking, a brake drum 22 is carried with the basket'shaftiassembly, and friction bands 23 are movable againstthe drum by action of ccinneetedair'cylinders 24. Inknownmanner, the bands normally 'are-heldffree'ofthe drum by springs l5 and are set by admitting air pressure to the cylinders 24 through an air line 25 leading from a solenoid valve BSV (Fis- 3) 'The 4treated `-solids -discharged "by discharger shoe 33 "fter each: spinning period pass out'of the'basketthro'ugh ""openng` 17a inthe 'basket' bottom'l. VA frustoconical n valve 26 fitting outlet 17a surrounds shaft 18 and is'movfable :vertically to expose 'the outlet during each disf'charging operation. Basket cap 16 has Aa central 'opening '16a affording-accesswto the interior `of'the lbasket. :Theentire'basket is surrounded by a' stationary curb "'27which collects the liquid'expeliedfduringspinning l"peri'odsand has a centrally'open top 28 providing supportffor the discharger mechanismvat'29, for avalve 4"'-liftingdevice at'31, and for aconventional sprayer 32 iur-'which is used for -washing solids' in the spinningv basket. -Detailsof-a suitabledischarger'mechanism are set iforth4 in United States' Patent No. 2,667,974. This mechlanism'includesa` housing-35 which carries the discharger "'shaft 34 and Ais Aswingable horizontally about a supporting stud (not shown) that projects upwardly from thef curb top 28. A'solenoid-valve DSVl (Fig. 3)v con- "'trls jtheV admissionof fluid lpressure fromr header 3&7 "fthrou'ghpressure -line 63-to `a cylinder formed in the rrhousing,whereby the housing is swung so as tolmove 40":the'discharger shaft and shoe outwardlyfrom a Vnormal *'or'rest' position -into engagement with solids inthe basket.

A tension spring'38 constantly urges the housing inthe opposite direction, so as to move the shoe inwardly away *from* the-'basket side kwall'when the valve DSVI is 'de- 'ener`gize`d.

p Verticalmovements of the'dscharger shoe are brought @about by the action of a fluid pressure cylinder-39 which is mounted in a vertical position alongside the shaft`34 a'dhas'i'i-ts -plunger =coupled with the shoe 33.

Slenoid valves'DSVZ and DSV3 control the admission bffuidj pressure to'theupper Vand lower ends of cylinder :139,trespectively, in; order to bring yabout downward and iupward irrio'vements'of 'the shoe. Each ofY these solenoid `valvesffisa"three-way valve connected with the pressure header 37. Solenoid valve DSVS'when dee'nergizcd'ad- *mitsi the pressure 'fluid'from header 37 into the lowerend bf-cylinder 39,-so that the discharger shaft and shoe nor- -"mally are'held'in a raised position near thertop ofthe f'bsket. 'When both DSV2 andDSVS are energized,=the

ohederlpressurelisfadmitted AthroughDSs/'Z into the top of cylinder 39 and the fluid pressure in the lower end 'iofthe cylinder is released -through i DSV3,=whereupon fitheldi'schargerfshoe vismoveddownwardly in the basket. 'l'I-leshoeis' raisedagain when the two solenoid valves are 'fdeerle'rgi'zi The-above-mentio'ned valve lifting device at 31-includes ilaiiuidlpressure-cylinder ydi) to which asupply oficomipressed'lair'iisbroughtby air -linesl66 and 67 controlled by? solenoid valves VLSVi and VLSVZ, respectively. The

S solenoidz valves AVLSVI and VLSVZ are three-way valves V`ywhiehnormally are deenergized. When they are 'deenergi`zd,'iiuid .Tpressure is maintained in the'v loweriend of 1c`yli-nder`40' through line 66,3solthat thelbasket valve-26 "-orn'i'allywillbefr-kept in its closed position. WhenVLSYl 37 is admitted through 'VLSVZ into the upper end of cylinder 40 and ,the lower end of the cylinder is vented through line 66 and valve VLSVl, whereupon the basket valve 26is lifted away from its seated position to open the basket outlet 17a.

The several phases of operation of the discharger mechanism at 29 are controlled through the agency of a Discharge Timer DT (Fig. 4), the electrical connections of which are diagrammed in Fig. 5.

The activation of the discharge drive DD andthe discharge timer DT is controlled through the agency of a zero speed switch ZS, shown at the top of motor MM in Fig. 2.

The loading of charge material into each centrifugal machine is eiected according to the disclosure of the aforesaid copending application Serial No. 261,258. A material supply tank 42 (Fig. 2) has a loading spout 43 for each machine. The spout is fitted at its lower end with a loading gate 44 which is positioned to deliver the charge material from the tank directly into the basket 14 through the openings in the curb top 28 and the basket top 16. The gate is opened by admitting tluid pressure to the upper end and venting the lower end of a pressure cylinder 45, whereupon piston rod 45a rocks lever 46 clockwise on its axis at 47 and raises the gate closure through link 48. When the pressure conditions in cylinder 45 are reversed, the gate is moved to closed position.

Air lines 49 and 50 conduct the pressure uid, e. g., compressed air, to or from the upper and lower ends of cylinder 45 from a supply line 52, depending upon the position of a control device or air valve (not shown) located inside a servo-motor control box 53. The control box is positioned on a pivot 54 according to the position of a link 55 which connects the control box to lever Inside the control box is a solenoid arranged to deliver pressure through air line 50 when the solenoid iis deenergized.

Reference should be had to said application Serial No. 261,258 for further particulars of the loading control mechanism. It should suce here to point out that a loading operation is started by energizing the solenoid inside control box 53 and is terminated by deenergizing that solenoid. When the solenoid is energized, the gate opens, box 53 is swung clockwise by link 55, the charge eeler 57 is swung toward the basket side wall by the resulting motion of link 56, and a limit switch LS is tripped by a cam at the top of the feeler shaft. As a wall of charge material builds up in the basket, the charge feeler is moved inward by this wall and members 56 and 58 are then positioned so as to cause a partial closing movement of the gate. That movement repositions the control box so that the gate stays open until a further inward movement of the feeler brings about a further gate closing movement. This progressive closing of the gate in accordance with the progressive building up of the charge continues until the charge wall has approximated a de- 'sired nal thickness, whereupon limit switch LS is oper- .ated to deenergize the solenoid in box 53 and thus cause the gate to move directly to its fully closed position.

INDIVIDUAL MACHINE. CONTROLS The functions of the several elements of each centrifugal machine may be initiated and controlled manually to any desired extent, but for normal operations an automatic cycle control system is provided for each machine, by which its operations are carried out automatically in the desired sequence. In the embodiment shown, this 6 system makes use of `control elements and operations like those disclosed in U. S. Patent No. 2,667,974, which are combined with other elements in ways to achieve the objjects of the present invention.

As diagrammed, the various control elements of each machine include push button switches and a selector switch 61 on panel P4 (Fig. 3), several solenoid valves nects that line to a Vent.

with pressure regulators on control framing CF, and electrical control relays, timers and motor contactors on remote control panels P2 and P3. In addition, the zero speed switch ZS of each machine has a low speed contact ZSZ which is closed as the basket speed approaches zero, e. g., at about 200 to 225 R. P. M., and which must be closed in order for the discharging functions to take place, and also a high speed contact ZS1 which normally is open but closes when the basket speed rises beyond a safe loading speed, e. g., at about 275 R. P. M.

, The control elements are interconnected electrically to operate as indicated by the wiring diagram of Fig. 5. In that diagram, relay contacts are shown separately from the respective relay coils by which they are opened and closed, in order that their functions may be clearly indicated. The contact or contacts belonging t., a certain relay are designated by corresponding reference characters, with or without sulixed numerals to distinguish between ditferent contacts of the same relay.

The push vbuttons on panel P4 close or open control circuits directly when pushed. These include buttons:

R, for starting a running or spinning period of the machine;

Load, for manually activating the loading control mechamsm;

OL, for omitting the loading operation so that troubles can be checked by manually running the machine through a cycle without loading the basket;

S, for manually stopping the machine at any time;

RS, for resetting the automatic controls before starting a new cycle;

Rev., for activating the reverse or discharge drive DD;

J, for manually jogging or holding main motor MM on its low speed winding if 'a loading speed is to be obtained manually;

W, for manually actuating valve WWSV to deliver washing uid through the sprayer;

ES, for the emergency stopping of the machine;

DB1, for manually actuating solenoid valve DSV1 to swing the discharger outward and inward; Iand DB2, for manually actuating solenoid valves DSV2 and DSV3 to move .the discharger down and up.

As shown in Fig. 5, the contacts of push buttons RS and ES are normally closed. Those of the remaining push buttons are normally open, except that push buttons OL and S have both normally open and normally closed contacts. Valve WWSV is a two-way solenoid valve on a washing fluid supply line (not shown). Valves DCSV, DSV1, DSV2, DSVS, BSV, VLSVI, VLSVZ, SSSVl and SSSV2are air solenoid valves conected with the pressure header 37, each having an active position in Whichit connects the header with a line to the element controlled by the valve and also another position in which it con- Valves DSV3 SSSVI and VLSVl are active when deenergized, so that they will continue suplying pressure to keep the discharger shoe in its raised or rest position and the syrup separator positioned to collect green liquor, and to keep the basket valve in its seated position, while the machine is spinning, and even when all the control circuits are open.

The timers indicated on panel P2 are adjustable time relays or time delay switches of known construction. They may be of the multiflex type wherein several individually timed contacts are incorporated in a composite unit, although an equivalent number of separate timer units would also serve. A process timer group PT lop'e'rtin of the 'discharge motrfDM. 'Thedriving motor "v motor contacts jcfonjtrolledby" the contactors L,H'an`d DMS of each machine are diagrammed in .EigfSa't The control ci'rcuit forf'each 'centrifugal VVrnachine .is L

eiier'gized Wli'enfswitclies C'ISWare closed inthe current 'supply'ilines 'L'l and `L2'of FigrS.` It motor'thermolgu'ardfnd a gyrtion switch are'the'n inactive, current Vflows"to`relay`XCR which closesits normally open XCR 'c acts to bring'control energy tothe circuits in-parallel Vwrth'ft'lie runvbutton'R (assuming that the protective 'overload relays LOL-and HOL (Figfjq) are inac :ti vt.`y and that theprotectivephase'failure relay FFR has closed its con- 'tac'tsf'in ltliellineto the RUNbutton). vWhen XCR is thus energiiedfits normally closed contacts leading to the @discharge-timer DT,-brakerelayBR andtbrake solenoid valve BSV are opened. If reset button RS Ais then depressed, those control elements are deenergized so that thel parts of the machine controlled by them may beinactive. Ati the Sametime, relay CR4 is energized through 4'normally 'closed contacts LR2 a'nd-'ZSZ` of Fig. 5.

The individual machine is now ready to enter into a cycle of'operations. lllustrativedetails of its operations according tothe diagram of Fig. 5 will be set forth hereinafter. Atvthis point, it is appropriate to point out that the extent of the operations performed automatically according tothe present embodiment willdepend upon` .thesetting selected for the selector switch 61,v which has three diterent positions designated as Load Speed, JMa'nual A 'and Recycle As further shown near the top of Fig. r5, thecontrol elements forreachmachine, according ito the present intventionfalso' include a recycle timer RCT. Thistinrer'is associated -w'ith'relays AC and AC1, `with a Cycle Cornpletelig'ht"and"with various contacts, in a group of circuits which lare 'energized only-if the'selectorswitch 61 isset either fat-its Load Speed position or its Recycle position. Y n if thefselector switch is set vat its .Manual position, the recycle timer RCT and other control elements just ,mentioned-aire kept deenergized, so thatrthere is no 'automatic actuation of the loading relay LR and Vprocess ltimer TI (shown near the middle or Fig. 5). In that event the individual machine can n be brought to loading speed 'through relay CR1 and contacter L, byrpushing run buttOnR; then it may be loaded by pushing the Load ibutton, whereupon4 it will automatically Apretlush the basket, Yload itself, accelerate, wash the basket charge, Spinat high (speed, decelerate, reverse itself, discharge it- 'self and come to rest with the'brake applied. Then it will ystay at rest until its controls are manuallyreset by use Aofllutton lRS and the main motor is manually restarted `by use ofwbutton R. t

lIttheV selector switch'is 'set at'its Load Speed position, ,control relay AC Vis kept energized to open the line be- `tween the-Runbutton and -relay CRI, andthe recycle timerwFtCT lwill take a part in the operations. After the cofrrlpletion of dischargingtimer RCT-maybe :energized throug'h discharge timer contacts DTS. RCT then will energize .rel-ay, ICR! through contacts l:RCTA vso as .to

'close CRI contacts' which energize contactor L and cause die klts'wjiieen'Enif'cutsf't, fo Sarthe "man maar Tle.EnachiiieA lifesjto af oadingfspeed, whereupon Io'adf uingfn'iayfbew achievedfby pushingthe Loadubuttn. 'ffe'r. loading, the 'controls will carry 'tle machine-through prescribed operationsfautomaticall-y untilit' is'againfr'eafdy tobe'lodedintheneirt cycle. p 1 fIf theselector'Aswit/chs V'set at Aits Recyclelpositiomnot nlythe 'operations Vobtained automatically at theLoad Speed :position butalso .the`loa`ding and turther 'cycle operations 'will bel brought about automatically, so 4that the entire A`cycle of `opleratio11s maynpeAperformed-arid restarted underd automatic control. This results, impart, from the connections Lmade through the selector switch fo'he feyleft/Ier,'andaSSQCtCOD/ml;elmemsr and to the loadingfrelay LR,` .Accorfdingly, -in this-setting of the controls, eachmachineA of rthe?illustrated embodiment, after-having been started onj one, c'yclefmjay `colitinuev running frepveatedly `through -itscomplete cycle `:of operations, includingv `starting, floadin'g, qacceleration, washing-drying (spinning artgfull speed), deceleration, reversal to the V-lnegative' discharging 1 speed, discharging, stopping,.resetting'andrestarting. That mode of opjeration 'will continueVlrowever, only if suitable conditions exist at the-end o iieach cycle, asxd'eterminedybythe-circuits -of the Irecycle timer RCT -and' by the battery "sequencecontrol circuits of'FigJ. 6.

More particularly, when selector switch 61 is set fat its Recycle position, these-conditions exist: 1Re1ay AC is energized and its contacts AC'are opened' to hold open the linegbetw'eent the RUNYbuttonand' controlI relay CRL Thefmachine having-fbeerr idle, its electricalcontrol elements 'will be; inca rlesetcondition, andeach of `the confacts DTS,4 RCT"-1;BST1R'ahdfRCT1 AWillbe open. Accordinglyfno' tenergy Twill ow: to the recycle' timer; so `its normally A,open contact RCTZ will he open, and relay CRI rwill 4'stay 'de'energ'ized :until:y something occurs infthe battery -ncontrols to ienergiz'e `RCT through contacts BSTIR. I0n 'the .othenhandfwhen' contacts BSTIR are closed through the' operationfof thebatterycontrols pres- 'ently tobefdescrihed,'stherecycle timer will be energized throughfnormallyclosed Cklcontfacts; rit will holdl'it'slf energized by closing :contacts iRCT-T; it 'lwill 'close tits RCT2 contacts Sto energize "CR-1, Vwhereupon i CRI co'ntacts in the line to contacter L will closeftof'sta'rt -the mainiotorfonitslow speedwinding; and through? further 'control circuitsirFtg.

. tions;

battery sequence timer'ST, which -functions as a ,steppigswitch -hayin'g a .plurality "of contacts, vincluding oneffor'eachuentrifugal machine; Y n

:otbattery sequence timer relays .fBSTR and ,BS'IIfR to fBSlSR, inclusive-including one rof ftlie 7,5 `:following for each machine;

Battery operating relayBOR; Battery stop relay BSR;

Starting relay SR;

Time delay relays TDR and TDR1; and Out time timer OT.

the starting relay, which in turn serves to energize the. battery sequence timer BST. 'Ihe battery sequence timerl itself has a timer-closed and timer-opened contact for4 each machine, i. e., contacts BSTl to BST8, inclusive,

and these contacts control the respective circuits to the.

battery sequence timer relays BSTlR to BSTSR, inclusive. Those relays, in turn, Ihave normally open contacts connected in parallel across the circuit to relay BSTR, so`

that BSTR is energized to close its contact BSTR in the circuit to the motor of the battery sequence timer BST whenever any one of the battery sequence timer relays is energized.

The respective relays BST1R to BSTSR also have twok normally open contacts in the circuits to the recycling timers RCT of the respective individual centrifugal machines (e. g., contacts BSTlR in Fig. 5). And the battery operating relay BOR has a normally closed contact in a circuit to the motor of each recycling timer RCT,

as also seen in Fig. 5.

Further, the circuit to the last of the battery sequence` timer relays, e. g., relay BSTSR, is connected with time de- I lay relay TDR so as to energize the battery when BSTSR,

is energized. TDR, in turn, has contacts in a circuit to relay BOR, whereby all the battery control relays will be deenergized Iat a predetermined time interval, say about 1 second, after the opening of contact BSTS.

The last-mentioned mode of operation will occur if the selector switch 69 is set at its Independent Recycling position. In that event, after the several centrifugal machines have been started in a desired timed sequence by the operation of the battery control, each machine may continue to recycle itself quite independently of the operations of the other machines of the battery. This manner of independent recycling, however, will continue only for as long as coinciding periods of acceleration of two or more of the machines do not cause a power ilow to the entire battery of machines in excess of a predetermined safe limit. That limit is determined by a feeder overcurrent relay (Fig. 6) in the power feed lines to the battery, which relay has a -nor-` mally open contact at I in a circuit to the battery operating relay BOR. Whenever the current flow to the battery exceeds the limit set by the overcurrent relay, BOR is energized to open the several BOR contacts in the RCT motor circuits of the several machines of the battery. It results that the recycling timers RCT of the individual machines cannot close their RCTZ contacts to energize their respective CR1 relays; so the individual machines may complete their pending cycles and come to rest, but none of them will start itself Iagain on a new cycle. When all of them are at rest, however, all of the several CRI contacts of the battery sequence controls will be closed and able to energize the starting relay SR of the battery sequence controls, whereupon those controls will restart the machines in the desired sequence, as described in detail hereinbelow.

If the selector switch 69 is set at its Group Sequencing position, all the cycles of the individual machines will be started at denite intervals under the continuous control of the battery sequence controls. In that position, switch 69 holds relay BOR energized to keep the normally closed BOR contact of each machine open at all times, thus keeping the recycle timers RCT of the individual machines arborea 10 subservient to the action of the battery seqncentiniet BST.

Further, the setting of switch 69 for Group Sequencing brings actively into the battery controls the circuits of 4 Fig. 6 leading to time delay relay TDRl :and to the Out Time timer OT, whereby the starting intervals of the individual machines may be selected so as to obtain any desired rate of production from the machines of the battery while keeping all the machines in service. It re sults that upon the energization of each of the battery sequence timer relays BSTlR to BSTSR, contacts BSTRl of relay BSTR are closed in the circuit to the out time timer OT. Timer OT then opens its OT contacts in the circuit to the motor of the battery sequence timer BST and stops that motor until after the expiration of a preset interval of time determined by the setting of OT. After that interval, the motor of BST is restarted. Thus the time setting of OT is added to the interval normally fixed by BST between the successive startings of different machines of the battery.

DETAILED OPERATIONS OF THE BATTERY SEQUENCE CONTROLS With all the centrifugal machines of the battery empty and at rest, and with the individual controls of each machine energized through switches ACSW and relay XCR, the selector switch 61 `of each machine is Set at its RE- CYCLE position. The battery of machines is now ready to be started by the action of the battery sequence controls.

A. Starting the machines If the maximum productivity of the battery is desired, selector switch 69 of the battery control is moved to its, Independent Recycling position. Then an attendant; presses the battery start button BB, and the following; operations take place:

1. Relay BOR is energized through a circuit closedl by the battery start button, whereupon:

(a) Normally open BOR contacts close to keep relay/f BOR energized. v

(b) Other normally open BOR contacts close in the line Vleading to the battery sequence timer BST and to the battery sequence timer relays BSTlR, etc., so the clutch of BST is energized, and contact BSTT closes in the circuit to the motor of BST.

(c) Since all the machines are at rest, all eight of the CRI contacts in Fig.V 6 are closed; so relay SR is energized.

(d) Normally open SR contacts then close to keep relay SR energizedv and to start the motor of the battery sequence timer.

(e) Meanwhile, relay BOR has opened the normally closed BOR contacts in the RCT motor circuit (Fig. 5) of each machine.

2. The battery sequence timer BST having been started in operation, an element of this timer closes contacts BSTI, whereupon:

(a) Relay BSTlR is energized;

(b) Normaly open BSTIR contacts close to energize relay BSTR; and

(c) Other normally open BSTlR contacts in the control circuits of machine #l (Fig. 5) are closed to energize both the clutch and the motor of the recycling timer RCT of machine #1. This timer keeps itself energized by closing its contacts RCTT. Then it closes its contacts RCTl to energize relay AC1 and thus reset the timers and relays of the machine. Contacts RCTl areA reopened shortly thereafter, whereupon timer RCT` proceeds to start the cycle of operations of machine- #l asfollows:

(1) Contacts RCT2 are closed by RCT, to energize con-- trol relay CRI. This relay, by closing normally Open- CRl contacts, holds itself energized and also closes aA circuit to the motor contacter L whereby the main- 'motor is started on its low 'speed winding. `At the Asame time, the normally closed CR 1 contacts of maclnne #1 in the circuits of Fig. 6 are opened.

(2p) Machine #l is accelerated by itspmotor MM to a speed limited by the setting of the Zero Speed Switch ZS, e. g., to not more than 275 R. P. M. At that speed, contacts ZS1 of switch ZS `are closed; contacts v ZS2 are opened; relay CRS is energized through contacts ZS1 and keeps itself energized; relay CR4 is deenergized by the opening of certain CRS contacts; and IotherpCRS contacts in the circuit to'contactor Lopen Ato deenergize contactor L and cause the centrifugal tocoast without motor power.

(3) When the speed of the coasting centrifugal drops to -a predetermined value, e. g., about 225 R. P. M., contacts ZS2 of the zero speed switch close again to reenergize CR4, whereupon CR3 is deenergized and con- "tactor L is again energized to activate the main motor and keep the centrifugal rotating at a speed suitable for loading.

(4) After a time interval determined by 'a setting of timer RCT, contacts RCT3 are closed in the circuits to the loading relay LR and to process timer T7. The wash water solenoid valve WWSV is then energized to start a preushing of the basket screens. When ltimer T7 times out, WWSV is deenergized, whereupon normally open contacts LR and T 7B are closed to keep relay LR energized and to energize the gate solenoid GS. The loading gate for machine #1 then is opened as described hereinabove. The charge feeler 57 moves into working position and limit switch LS is tripped to energize relay LRI which seals itself in circuit and "closesits contacts in the circuit to relay LR2. A charge yenters the rotating basket of the machine.

(5) When the desired charge thickness is reached, limit switch LS is returned to its normal position, and relay LR2. is energized. Y At this point, 'certain LR2 contactsn the circuit to relay LR are opened to de- 'energi'ze relay LR and solenoid GS; also, normally open LR2 contacts in the circuit to control timer VCT and timer T1 are closed to energize those timers; also, the normally closed LR2 contacts in thercircuit 'to zere-speed switch contacts ZS1 and ZSZ are opened Vto deenergize relays CR?, and CR4.` Thus themotor contactor L is freed from the speed limitation imposed bythe zero speed switch. Y l

(6) From that point on, the individual machine Aproceeds through its cycle substantially as disclosed in nthe aboveidentied patent and as described in further 'detail hereinafter.

3. Meanwhile, at an appreciable interval after the closing of contacts BSTI, e. g., after two (2) Seconds, the battery sequence timer BST opens those contacts to deenergize relays -BSTIR and BSTR.

4. -Battery sequence timer BST now continues to progress through its successive steps of closing 'contacts BSTZ to BST8 and thus energizing relays BSTZR to BSTSR at definitely timed intervals which are determined by the speed or the settings of timer. Tf the eight (8) centrifugal machines each have a normal duty cycle of 144 seconds, and if they are to be kept operatingat maximum capacity with a minimum overlapping of their periods of acceleration and high power consumption, they will be started successively "at intervals of l--4='18 seconds Accordingly, lcontact 13S-T2 is closed eighteen (18) seconds after the closing of BSTl, whereupon:

di) esnystzs energized; (b) 'Noifmally open BSTZR contacts -close to energize (f) 'other ae'r'mily 'apen 'i'srn difie in the "cnentrasse' trol circuits of machine #2 are clsed to energize both the clutch and the motor of the recycling timer RCT of machine #2. This occurs in the same way as described in paragraph 2(0) yabove with respect to the BSTIR contacts of machine l. Timer RCT of machine #2 proceeds to 'start that machine in the way described underv paragraph 2(c) above.

y5. Two (2) seconds after the closing of contact BSTZ, that contact is opened by BST to deenergize relays BSTZR and BSTR. A l

6. The remaining machines are started at l8-second intervals in the saine way s machine #l and machine #2v but through the successive operations of contacts BST3 'to BSTS, inclusive.

7. When the lastmchine of the battery isthus started by the closing` of BSTS, the time delay relay TDR is energized. This relay measures a suitable interval, say of about l second, after the opening of contact BSTS, whereupon 'IDR opens its contacts in the circuit to the battery operating relay BOR so as to deenergize BOR and open the circuits to all the relays of the battery control system. That system thus is inactivated until an occasion arises for it to stop or restart the operations of the several machines.

B. Stopping and restarting the machines to regain l sequence l. When th'e cycles of the independently recycling machines become su'inci'ently out of "step that 'an excessive drain on the power supply to the battery may be im` minent, e. "g., when the acceleration periods of the cycles o`f 'more than two or the eight machines begin to overlap, the predetermined capacity 'of the feeder over-current device "on the power supply lines to the battery will be exceeded. The contact a't I in the battery control circuits (Fig. 6) is then closed, whereupon:

(1a) Relay BOR is energized and keeps `itself energized;

(b)The BOR contacts in the RCT motor circuits of all the eight `machines are opened to prevent the continued recycling -of the machines; and

(c) Other normally open BOR contacts in 4the battery control circuits. close to energize the clutch of the battery sequence timer BST.

2. YAll the m'acl'iin'e's then in the course of a cycle contine to operate until their respective cycles are cornpl'e'ted, 'each machine coming to rest for lack of action by its recycling timer to Vrez-energize its Y'CR-1 relay.

3. When fall thev machines have stopped, all the `Veight CRl contacts in lFig. 6 are closed; vso energy now ows to 'relay SR, and it closes contacts Ito 'energize the motor of battery'se'quence timer BST.

4. YThe lbattery sequence timer BST now enters into its step -by step operations to restart the `eight machines in the desired timed sequence, e. ig., lat l8-'secon'd 4intervalsfin the manner vdescribed in section above.

C. Stopping the machines .to discontinue operations Whenever it is desired 'to 'discontinue the 'ope'r'atio'n's of the Vcentrifugal "battery, 'the battery stop button BS may be pressed. This energizes lrelay BSR which seals itself in circuit, opens the circuits to the battery sequence timer and battery sequence timer relays, and eriergizes relay BOR. The BOR contactsof the individualmachine controls are then opened, so 'that VVeach centrifugal wilt complete its pending cycle and Yremain a't rest. Pressing the battery start button BB will braise :the battery control to restart the machines in 4the predetermined sequence described above.

D. rlp 'seltincit'g "to 'rglz't'e productivity fIf bthe 1'rate Aof :production desired from the machines of the battery is less than' that obtained by operating them on their normal cycles, the 4desired lvreduced rate may be established and maintained while keeping all the machines in service on cycles started in a predetermined sequence, through the action of the battery control system. F or this purpose, the selector switch 69 of the illustrated battery'control is set at its Group Sequencing position. If the machines are operating at that time, this change will lirst cause them to complete their individual cycles and come to rest.

Suppose, for example, that the maximum useful cycle time of each machine is about 210 seconds, a longer cycle being likely to render the solids in the basket too dry and hard for proper discharging. Suppose also that the rate of production desired would call for an average cycle time of 280 seconds if all the machines were kept in service. This means that an average idle time of 280 minus 210, or 70 seconds, should be added to the maximum useful cycle time of each machine. It also means that the machines should be started successively at intervals of or 35 seconds, in order to have equally spaced starts im posing the minimum drain on the power supply to the battery. Accordingly, the appropriate timers in the individual machine controls are Set to give a cycle time of 210 seconds for each machine, and the out time timer OT in the battery control is set to measure an interval of 17 seconds between the time when it is energized and the time when it acts to deenergize itself and restart the motor of the battery sequence timer BST.

1. Those settings having been made, when all the machines come to rest, the eight closed CRI contacts of Fig. 6 cau-se relay SR and the motor of battery sequence timer BST to be energized. Timer BST then proceeds to close its BSTl contact and start machine #1 as described in section A. 2. above.

2. At the same time, relay BSTR is energized and its contact BSTRl closes to energize the clutch coil'of the out time timer OT. Normally open OT contact is then closed to seal this clutch coil in circuit.

3. Two seconds later, when BST] is opened by timer BST, relays BSTIR and BSTR are de-energized and contact BSTRZ of BSTR closes to energize the motor of timer OT, contact BSTRI then reopening, whereupon:

(a) Timer OT starts timing;

(b) Normally closed OT contact in the motor circuit of BST is opened to interrupt the operations of the battery sequence timer.

4. Seventeen (17) seconds after the closing of contact BSTl, the out time timer OT times out, resets itself and restores -the circuit to the motor of BST; so the battery sequence timer resumes its operation. Thus an interval of 17 seconds is added to the 18 second interval otherwise ixed by the battery sequence time.

5. Thirty-tive (35) seconds after the closing of contact BSTl, the battery sequence timer closes its BSTZ contact and machine #2 is then started as previously described. The out time timer OT again adds 17 seconds to the 18 second interval of BST.

6. Machines #3 through #8 are started in the same manner, at intervals of 35 seconds.

7. Finally, when contact BST8 is closed to start machine #8, a normally open contact BSTSR of relay BSTSR is closed to energize time delay relay TDRl. This relay then seals itself in circuit and closes its contact TDRI (AUX) in the circuit to the battery sequence timer BST, at the same time opening its normally closed contact in that circuit. When TDRI is energized, TRD also is energized to keep BST energized through contact TDR (AUX). Two (2) seconds after the closing of contact BSTS, that contact is opened and the out time timer OT is started. Time delay relay TDR 1s deenergized at the same time, thus opening its contact TDR (AUX) and deenergizing the battery sequence timer BST, which resets itself. One (l) second later closes its normally closed TDR contact, but the battery sequence timer is not restarted because the out time timer meanwhile is operating.

After the preset 17 seconds of its operation, timer OT opens contacts which deenergize OT and relay TDRl at the same time. At this point, the two TDRI contacts in the circuit to the battery sequence timer are opened. TDRI now operates for an interval of 16 seconds, at the end of which it closes its normally closed TDRl contact in the circuit to BST and thus restarts the battery sequence timer.

It results that an interval of 2|17l16 seconds is interposed between the time of the closing of contact BSTS to start machine 8 and the `time ofthe reclosing of contact BSTl by the reset battery sequence timer BST. So machine #l is started on a new cycle 35 seconds after the starting of machine #8 and 280 seconds after the previous starting of machine #1.

DETAILED OPERATIONS OF AN INDIVIDUAL MACHINE A detailed description of the operations of an individual centrifugal machine through the loading period of its cycle is set forth in paragraphs (1) to (6) under section A. 2. above. From the point of the deenergization of relays CR3 and CR4 to begin the acceleration of the loaded basket, the operations occurring according to the diagram of Fig. 5 are as follows:

1. Contactor L being energized, the loaded basket is accelerated by the operation of motor MM on its low speed winding. Timers CT and T1 meanwhile are operating.

2. After a preset interval, control timer contact CTI is closed to energize relay CR2, whereupon contactor L is deenergized, contactor H is energized to connect motor MM on its high speed winding, and the motor of timer CT is deenergized. The basket now proceeds to ac celerate to its full speed.

3. Meanwhile, timer T1 times out to close its contact TIB and energize timer T2 which closes contact T2C in the circuit to the wash water solenoid valve WWSV and starts a first washing of the basket charge.

4. After a preset interval, timer T 2 times out to open contact T2C and stop the first washing operation. At the same time it starts timers T3 and T5 by closing contact TZB.

5. After a preset interval, timer T3 times out to close contact T3B, energize timer T4 and open contact T3C, whereupon contact T4C is closed to energize WWSV and start a second washing operation.

6. After a preset interval, timer T4 times out to terminate the second washing operation by opening contact T4C, and to energize timer T6.

7. Meanwhile, timer T5 has timed out to close contact TSB and energize the syrup separator solenoid valves SSSVI and SSSVZ, whereupon a syrup separator (not shown) is shifted to separate wash syrup from the mother liquor previously purged from the basket charge.

8. After a preset spinning time has elapsed, timer T6 times out to open its contact T6B in the circuit to relay CRZ, whereupon that relay is deenergized, motor contactor H is deenergized, the motor of control timer CT is restarted, and contactor L is energized to connect the motor MM on its low speed winding for a period of regenerative braking.

9. After a preset interval, timer CT closes its contact GT2 to energize the brake relay BR and the brake solenoid valve BSV. Relay BR seals itself in circuit andopens contacts in the circuit to the motor contactors L and H. Thus, the motor MM is disconnected from its power lines and the brake 23 is applied to stop the machine.

l0. When the machine has decelerated to a speed of about 300 R. P. M., timer CT closes its contact CTS to energize lrelay CR3 and :bring the zero speed switch contacts into the circuits.

l1. When the basket speed falls to about 225 R. P. M., contact ZSZ closes to energize relay K4. Normally open CR4 contacts then close to hold CR4 energized, to start the discharge timer DT, and to energize the valve lifter solenoid valves VLSVI and VLSVZ. The basket valve 26 thus is lifted away from the discharge outlet 17a as the basket comes to a stop.

12. Discharge timer .contact DTZ is now closed to energize contacter 'DMS and the discharge clutch solenoid valve DCSV. A normally closed DMS contact is opened at the same time Vto deenergize the brake solenoid valve BSV. Thus, the mechanical brake is released and the discharge drive DD operates to bring the `basket toa `speed of Vabout 30 R. P. M. in reverse direction. 1,3, After a preset interval, Adischarge 4timer contact DT3 closes to energize solenoid valve DSVI which causes the discharger shoe 33 to be moved outwardly into the .basket charge. After .a further interval, contact DT4 is closed and solenoid valves DSV2 and DSV3 are energized Ato cause the downward movement ,of shoe33 in the basket. After further intervals, contact DT3 is opened, deenergizing DSV1 so that the shoe is Withdrawn from the basket wall by spring 38, and contact DT4 is opened Ito deenergize valves DSV2 and DSV3 so that the discharger shoe moves upv/'ard to its normal rest position.

14. After a preset interval, discharge timer Contact DTZ is opened to deenergize contacter DMS and discharge solenoid valve DCSV, whereupon the discharge drive DD becomes inactive, the brake 23 is applied and the basket comes to rest.

l5. Finally, at a preset time, discharge timer contact DTS is closed in the circuits to the recycle timer RCT. If the battery control permits, the recycle timer then starts operating. Its first action is to close contact RCTI and energize relay AC1, whereupon normally closed contact AC1 is opened in the circuit to all the timers except RCT; so all those timers and the related relays reset themselves. Timer RCT next opens its` RCTI contact, and the controls of rthe individual machine are now ready to enter into a new cycle of operations through the `closing of contact RCTZ as described under section A. 2. above. e

While the group sequencing operations to obtain reduced productivity are carried out in 'the illustrated embodiment by holding each machine at rest for a definite time after it has been discharged and then starting its rotation in a new cycle to bring it to loading speed, a similar mode of operation can be obtained in other ways. For example, if the material processed in the machines is of a kind that will not become too dry and hard for proper discharging when subjected to a long drying period, the sequential recycling of the individual machines by the battery control may occur by starting their` respective periods of deceleration from full speed. In this event, the drying period of their cycles is lengthened or shortened by the action of the out time ltimer to obtain the desired rate of production from the battery. Another Way of Iachieving a similar mode of operation is `to effect the sequential recycling of ithe individual machines by the battery control at the start of the final working operations of their respective cycles, so that any time to be added to their cycles will be added to their purging periods. This may increase the extent of purification of the basket charge lWithout adding objectionally to its dryness and hardness at the time of the discharging operation.

It is to be understood that the foregoing detailed descriptions and the accompanying drawings are illustrative and that the combinations Vand improvements herein disclosed may be embodied in various other ways without departing from the invention defined by the claims.

What is claimed is:

` 1. l'In a heavy Ycentrifugal installation including Aa plurality `of cyclical centrifugal machines each 'having .its own control system for automatically 'programming the machine throughV a `predetermined cycle 'of operations independently ofthe `cycles of the other .machines and each having recycling means connected with said systemY for causing the machine 'toenter into Aand automatically to repeat said cycle, `a battery control `comprising a plurality of actuators respectively operable to activate said recycling kmeans 'of said machines individually, timing means 'having a tplurality 4of Icorrelated timing 'elements respectively connected individually with said actuators and operative successively at predetermined intervals to operate said Aactuators in a predetermined timed sequence, and 4means lfor starting said Atiming means, whereby the machines Aare started on their respective Ycycles in apredetermined timed sequence.

2. In a heavy centrifugal installation including 'a plurality of cyclical centrifugal machines each having its own control system for automatically programming the machine through a predetermined cycle of operations independently of the :cycles 'of the other machines and each having recycling means connected Ywith fsaid system for causing the machine to .enter into and automatically to repeat said cycle, a battery control -comprising a plurality of actuators respectively operable to activate said recycling means of said machines individually, timing means having a plurality 'of correlated timing elements respectively connected individually with said actuators and operative successively at predetermined intervals to operate said .actuators in a predetermined timed sequence, means for starting said timing means, whereby the machines are started Aon their respective cycles in la predetermined -timed sequence, and means rendered operative upon the starting of the last-to-bestartedof said machines for inactivating said battery control, so that the machines will repeat their respective cycles independently of each other and of said battery control. I

3. In a heavy centrifugal installation including a plurality of cyclical centrifugal machines each having its own control system Vfor programming the machine through a predetermined cycle of operations independently of the cycles of the other machines `and each having recycling means connected with said system for causing vthe machine to enter into and automatically to repeat said cycle, a battery control comprising means rendered operative upon the -occurrence of an inordinate ow of power to said machines for inactivating the recycling means of `all said machines, so that `the machines in operation will complete but not vrepeat their cycles, a plurality of actuators respectively operable to activate said recycling means individually, timing means having aplurality of correlated timing elements respec- V tivelyconnected individually with said actuators and operative successively at predetermined intervals to operate said actuators in a predetermined timed sequence, and means rendered operative when all the machines in operation have lcompleted their `cycles for restarting said timing means, whereby the machines are restarted on their respective cycles in a predetermined timed sequence. Y

4. In a heavy -centrifugal installation including a plurality of cyclical centrifugal machines reach having its own contr-ol system for automatically programming the machine through a predetermined cycle of operations independently -offthe cycles of the other machines and each having recycling Ameans connectedY with said system lfor `causing the machine to enter into and automatically -to repeat said cycle, a battery control cornprising a plurality of actuators respectively operable to activate said Yrecycling means individually, timing means having a plurality of correlated timing elements respectively connected individually with said actuators and operative successively at predetermnied intervals to operate said actuators in a predetermined timed sequence, manually operable means for starting said timing means, whereby the machines are started on their respective cycles in a predetermined timed sequence, means rendered operative upon the starting of the lastto-be-started of said machines for inactivating said battery control, so that the machines will repeat their respective cycles independently of each other and of said battery control, means rendered operative upon the occurrence of an inordinate ilow of power to said machines for inactivating the recyclnig means of all said machines, so that the machines in operation will complete but not repeat their cycles, and means rendered operative when all the machines 'm operation have completed their cycles for restarting said timing means, whereby the machines are restarted on their respective cycles in a predetermined timed sequence.

5. In a heavy centrifugal installation including a plurality of cyclical centrifugal machines each having its own control system for automatically programming the machine through a predetermined cycle of operations independently of the cycles of the other machines and each having recycling means connected with said system for causing the machine to enter into and automatically to repeat said cycle, a battery control comprising a plurality of actuators respectively operable to activate said recycling means individually, timing means having a plurality of correlated timing elements respectively connected individually with said actuators nad operative successively at predetermined intervals to operate said actuators in a predetermined timed sequence, means for starting said timing means, an adjustable delay timer, means responsive to the operation of each of said timing elements for starting said delay timer and interrupting the operation of said timing means, and means operated by said delay timer after a predetermined interval of its operation for restarting said timing means, whereby the machines are started on their respective cycles in sequence at intervals determined by the intervals of operation of said timing elements and the adjustment of said delay timer.

6. In a heavy centrifugal installation including a plurality of cyclical centrifugal machines each having its own control system for automatically programming the machine through a predetermined cycle of operations independently of the cycles of the other machines and each having recycling means connected with said system for causing the machine to enter into and automatically to repeat said cycle, a battery control comprising 'a plurality of actuators respectively operable to activate said recycling means individually, timing means having a plurality of correlated timing elements respectively con` nected individually with said actuators and operative successively at predetermined intervals to operate said actuators in a predetermined timed sequence, means for starting said timing means, an adjustable delay timer,

means responsive to the operation of each of said timing elements for starting said delay timer and interrupting the operation of said timing means, means operatedV by said'delay timer after a predetermnied interval of its operation for restarting said timing means,whereby the machines are started on their respective cycles in sequence at intervals determined by the intervals of oper- References Cited in the file of this patent UNITED STATES PATENTS 1,726,674 Lockett Sept. 3, 1929 2,130,864 Steps Sept. 20, 1938 2,264,247 Neuman Nov. 25, 1941 2,667,974 Hertrich Feb. 2, 1954 

